DE1675501A1 - Device for distributing flow media to several passage openings - Google Patents

Description

Keyword: "flow distribution"

Deggendorfer Werft and Deggendorf / Donau, March 7th, 1968 Eisenbau, Ges.m.Td.H.

F. Pat

Device for distributing flow media to several Durchtrittsöff openings

In various technical fields, especially in the chemical industry and related fields Industries, liquids or gases are often in a certain ratio on several to each other to distribute parallel openings or pipes. This is the case with tubular heat exchangers, columns and Reaction apparatus into consideration. From the formula

2 gb

you can see which factors are important. If you take into account that

f = passage cross-section (of an opening or

of a pipe) in m
q. = Flow rate in m / see

= Total drag coefficient (due to contraction, friction, impact, etc.)

h = pressure head in m liquid column V2 g = 4.43 - constant value.

it follows that a medium can only then be evenly distributed over several passage openings

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can if in front of these openings at the same Individual cross-sections of the same and otherwise identical conditions with regard to the influence on the total drag coefficient the same pressure level of the medium is present everywhere.

However, the latter is not always the case. Unequal pressure levels can result from inflow paths of different lengths between a pressure source (pump, propeller, etc.) and the individual passage cross-sections and / or through result in different flow resistances in the individual flow paths. Such relationships apply, for example for reaction apparatuses with a tube bundle, with one for even exposure of all tubes a certain heat exchange medium in the end areas of the tubes in the transverse direction and in the intermediate central region in the longitudinal direction of the same will. In this context, one has distribution plates between the transverse and longitudinal flow areas of the pipes arranged with passage cross-sections proportional to the pressure height at the respective points.

The invention is based on the above-mentioned object To solve the problem in a different way, because it is not always easy and practical for plate openings or pipes to provide different passage cross-sections in order to achieve a uniform or otherwise predetermined one To achieve distribution of a flow medium.

The invention "consists in that the openings at

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same minimum control section on the inlet side in this way are designed differently that the beam cross-section via the total drag coefficient, taking into account the pressure prevailing at the point in question is influenced in terms of a desired flow rate.

In this way, all openings of a plate can initially be made the same or the same everywhere Use pipes, which is often advantageous for manufacturing reasons. Also is the determination of the individual subsets with the help of the inlet shape of each opening or each pipe dependent drag coefficient, especially with low gradations. The size of the drag coefficient Depending on the factors that are decisive for it, it can be done arithmetically or experimentally relatively easy to set.

Depending on the given conditions, certain minimum pressure differences can be decisive for the different design of the openings on the inlet side. In addition, the idea of the invention can be carried out both with openings in a plate and with openings in plugs inserted at the inlet end of pipes, namely in such a way that the openings from the or each point of the relatively highest pre-pressure to the other points on the inlet side according to the pressure gradient in the sense of a larger beam cross-section, increasingly widened in a funnel-shaped manner. 209824/0774 ^8A &

- A -

If necessary, it can be advantageous that the openings also differ on the outlet side are trained. Likewise, the friction, which is also part of the total drag coefficient, can also be can be changed by changing the length of the cylindrical passage openings (e.g. inserted Cans, fabric plugs of different lengths, etc.).

The object of the invention is shown in the drawing in several embodiments, for example.

Fig. 1 shows a vertical longitudinal section (plane I-I) Part of a heat exchanger with a bundle of parallel tubes 1 extending between an upper tube sheet 2 and a extend not shown lower * tube sheet. Slightly below the upper tube sheet and parallel to it, thus also transversely to the tubes is a plate 5 which surrounds the tubes tightly, but between the same a number of passage openings, in groups with 4, 5) 6, which, like the tubes, are arranged in rows parallel to them. A corresponding plate, not shown, can be located slightly above the lower tube sheet.

The arrows A and B indicate the flow directions of a heat exchange medium, which is in the upper end area the pipes 1 brought up transversely to these and then continued along the pipes after flowing through the plate 2 will.

Fig. 2 gives a horizontal cross-section through the

BATH ORIGINAL

Order according to FIG. 1 in level II-II again, ie 2.0 9824/0774

between the tube sheet 2 and the plate 3 · where is to see that both the tubes 1 and the passage openings in the plate 3 running transversely to the direction of flow A of the heat exchange medium and alternating Staggered rows are arranged. In practice, therefore, several, e.g. two consecutive Rows are combined to form common groups 4, 5, each of which is located on the entry side there is about the same pressure. Within each group, the passage openings are formed the same, while they have different entry forms in the successive groups.

3 leaves these group-wise differences in the passage openings arranged in the plate 2 4, 5, 6 can be seen on a larger scale in a representation corresponding to FIG. 1.

The passage openings 4 in the first two rows, the first and with the incoming heat exchange medium the relatively greatest pressure can be achieved have a sharp leading edge 7. This results in a compared to the diameter d of these passage openings, which is the same everywhere, the jet cross-section is relatively greatly reduced S-j.

The passage openings 5 in the next two rows have an entry side with the same diameter d small funnel-like enlargement 8. This also results in a somewhat less reduced cross-beam

Section S ₂ . BAD ORIGINAL

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The passage openings 6 in the last two rows, those from the oncoming heat exchange medium last on the relatively longest route and with the relatively lowest Pressure - after overcoming the greatest resistance caused by all pipes in front of it - can be reached, have an even larger funnel-like widening on the inlet side with the same diameter d which extends almost to the exit-side end transverse * cut extends. This results in a beam cross-section that is barely reduced compared to the diameter d s-z

The importance of this different design of the passage openings is that in the area the highest pressure on the inlet side (denoted by h in the formula given in the introduction) and the resulting Due to the maximum passage speed, the jet cross-section is reduced so much that the in the Unit of time flowing through the amount of heat exchange medium is only as large as in the other areas in which lower pressures on the inlet side and accordingly lower passage speeds, but there are relatively larger jet cross-sections. ,.

The differences on the inlet side between the various groups 4, 5, 6 of the passage openings are at the illustrated embodiment especially; large in order to make the sense of the inventive idea understandable. In reality it is usually only a relatively minor deviation ^ a, because the pressure

j ^ 209824/0774

_ ₇ _

differences in altitude are only slight and therefore one accordingly minor correction due to the total ■ drag coefficient suffice. That is precisely why it is according to the invention proposed measure, in addition to the comparatively simpler calculation, also for the practical Application particularly simple and therefore advantageous because for the production of all passage openings the same drilling tool with the same minimum cross-section can be used »The subsequent operation, which is then usual anyway, for" improving the drag coefficients deburring, smoothing and, if necessary, countersinking the edges or surfaces can be done at the same time to differently influence the drag coefficients.

Figure 4 illustrates in the same way as Pig. 3 a Another arrangement in which the tubes 10, which open again at their upper end into a tube sheet 11, through the Passage openings 12, 13, 14 of the divider plate 15 are guided. The openings have something larger diameter or minimum diameter than the Tubes, so that around the latter there is an annular gap that has the same width or the same width in the area of all tubes Has minimum width.

In contrast, the passage openings are also designed differently on the inlet side in this arrangement, namely entirely in accordance with the previous arrangement, i.e. in that of the heat exchange medium flowing in from the side (see arrow i first reached area with an essentially unbroken edge 16, in the next area with a relatively small funnel-shaped enlargement 17 and

2 0 9 8 2 A / 07 7 U ' § _Ä ß ORIGINAL - 8 -

in the last area, with a larger funnel-shaped widening 18. Here, too, these differences between the different groups of passage Hopes are shown in greater detail for a better understanding than it really is the pail.

Pig. 5 and 6 show a further embodiment of the invention in vertical longitudinal section (plane VV) and in plan view, respectively. This involves the distribution of a liquid flowing over a retaining wall 19 in the direction of arrow A over a plurality of tubes 20 of the same size, which are arranged behind the retaining wall in parallel rows and which are welded into a horizontal plate 21. Plugs 22, 23, 24 are inserted into the upper ends of the tubes protruding beyond this plate to a lower height than the retaining wall, all of which have the same minimum passage cross-section, but are designed differently on the inlet side. According to the invention, these differences consist in the fact that the plugs 22 in the two front ones correspond to the liquid level 25, which falls somewhat in the flow direction A behind the retaining wall 19 from row to row of tubes, and the resulting decreasing dynamic pressure heights h ^, h ^, h ~ Rows of tubes have a minimum cross-section reaching to the leading edge, while the plugs 23 in the two following rows of tubes have a small inlet funnel and the plugs 24 in the last two rows of tubes have a larger inlet funnel, which can also be formed by correspondingly rounding off the leading edge can. _Q

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On the outlet side, all stoppers have a diffuser-like shape Extension to a flow-wise favorable transition from their minimum passage cross-section to create the larger clear pipe cross-section. Such expansions on the exit side can optionally also be designed differently to complement the entry-side design of the passage openings their total resistance coefficient in the sense of the "intended distribution of the Fluid to "affect.

The invention is not only applicable to uniform Distribution of a flow medium with unequal inlet-side Pressure heights, but also in the opposite case, i.e. for a certain amount of irregularity Distribution of a flow medium with the same or otherwise not corresponding to this distribution pressure heads on the inlet side.

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Claims (7)

Keyword: "Flow distribution" Deggendorfer Werft and Deggendorf / Donau, den. March 7, 1968 Eisenbau, G-es.m.b.H. P. Bat "· Claims: 1. Device for distributing flow media in a "specific ratio to several passage openings, in front of which pressures of different levels prevail, characterized in that the openings (4, 5 ₅ 6; 12, 15" are designed differently on the inlet side with the same minimum cross-section, that the jet cross-section (s-,, Sp ₁ s ^) is influenced by the total drag coefficient (μ.) taking into account the pressure prevailing at the relevant point in terms of a desired flow rate. '; 2. Device according to claim 1, characterized in that certain minimum pressure differences are decisive for the different design of the openings on the inlet side, 3. Device according to claim 1, characterized in that that the openings (4, 5 »'6; 12, 13» 14) are in a plate (2; 15) are » 4. Device according to claim 1, characterized in that that the openings are in at the inlet end of pipes . 209824/0774 - 11 - (20) inserted StcP'fen (22, 25, 24) are located. 5. Device according to claim 1, characterized in that the openings (4, 5, 6; 12, 13 »14) from the or each point of the relatively highest pre-pressure to the other points on the inlet side according to the pressure gradient in the sense of an increasing Beam cross-section (s ,,, Sp ₅ s.,) Are increasingly funnel-shaped. 6. Device according to one or more of the preceding claims, characterized in that the openings are also designed differently on the outlet side. 7. Device according to one or more of the preceding claims, characterized by the application to the Distribution of a liquid in tubular heat exchangers, columns or similar devices. 209 824/077 Blank page e